Classification of groups of prime-cube order: Difference between revisions

Revision as of 23:05, 10 April 2011

Statement

Let $p$ be a prime number. Then there are, up to isomorphism, five groups of order $p^{3}$ . These include three abelian groups and two non-abelian groups. The nature of the two non-abelian groups is somewhat different for the case $p=2$ .

For more information on side-by-side comparison of the groups for odd primes, see groups of prime-cube order. For information for the prime 2, see groups of order 8

The three abelian groups

The three abelian groups correspond to the three partitions of 3:

Partition of 3	Corresponding abelian group	GAP ID among groups of order $p^{3}$
3	cyclic group of prime-cube order, denoted $C_{p^{3}}$ or $\mathbb {Z} _{p^{3}}$ , or $\mathbb {Z} /p^{3}\mathbb {Z}$	1
2 + 1	direct product of cyclic group of prime-square order and cyclic group of prime order, denoted $C_{p^{2}}\times C_{p}$ or $\mathbb {Z} _{p^{2}}\times \mathbb {Z} _{p}$	2
1 + 1 + 1	elementary abelian group of prime-cube order, denoted $E_{p^{3}}$ , or $C_{p}\times C_{p}\times C_{p}$ , or $\mathbb {Z} _{p}\times \mathbb {Z} _{p}\times \mathbb {Z} _{p}$	5

The two non-abelian groups

For the case $p=2$ , these are dihedral group:D8 (GAP ID: (8,3)) and quaternion group (GAP ID: (8,4)).

For the case of odd $p$ , these are prime-cube order group:U(3,p) (GAP ID: ( $p^{3}$ ,3)) and semidirect product of cyclic group of prime-square order and cyclic group of prime order (GAP ID: ( $p^{3}$ ,4)).

Facts used

Prime power order implies not centerless
Center is normal
Cyclic over central implies abelian
Lagrange's theorem
Equivalence of definitions of group of prime order: This basically states that any group of prime order must be cyclic.
Classification of groups of prime-square order
Structure theorem for finitely generated abelian groups

Proof

First part of proof: crude descriptions of center and quotient by center

Given: A prime number $p$ , a group $P$ of order $p^{3}$ .

To prove: Either $P$ is abelian, or we have: $Z(P)$ is a cyclic group of order $p$ and $P/Z(P)$ is an elementary abelian group of order $p^{2}$

Proof: Let $Z=Z(P)$ be the center of $P$ .

Step no.	Assertion/construction	Facts used	Given data used	Previous steps used	Explanation
1	$Z$ is nontrivial	Fact (1)	$P$ has order $p^{3}$ , specifically, a power of a prime		Fact+Given direct
2	The order of $Z$ cannot be $p^{2}$	Facts (2), (3), (4), (5)	$P$ has order $p^{3}$		[SHOW MORE] If $Z$ has order $p^{2}$ , then $P/Z$ (which exists by fact (2)) has order $p$ (by fact (4)) hence must be cyclic (by fact (5)). Then, by fact (3), $P$ would be abelian, but this would imply that $Z=P$ , in which case the order of $Z$ would be $p^{3}$ .
3	The order of $Z$ is either $p$ or $p^{3}$	Fact (4)	$P$ has order $p^{3}$	Steps (1), (2)	[SHOW MORE] By fact (4), the order of $Z$ must divide the order of $P$ . The only possibilities are $1,p,p^{2},p^{3}$ . Step (1) eliminates the possibility of $1$ , and step (3) eliminates the possibility of $p^{2}$ . This leaves only $p$ or $p^{3}$ .
4	If $Z$ has order $p$ , then $Z$ is cyclic of order $p$ and the quotient $P/Z$ is elementary abelian of order $p^{2}$	Facts (3), (4), (5), (6)	$P$ has order $p^{3}$ .		[SHOW MORE] If $Z$ has order $p$ , then by fact (5), $Z$ must be cyclic. By Fact (4), $P/Z$ has order $p^{2}$ . Further, by fact (3), $P/Z$ cannot be cyclic, because if it were cyclic, then $P$ would be abelian, which would mean that $Z=P$ has order $p^{3}$ . Thus, $P/Z$ is a non-cyclic group of order $p^{2}$ . By fact (6), it must be the elementary abelian group of order $p^{2}$ .
5	If $Z$ has order $p^{3}$ , $P$ is abelian.		$P$ has order $p^{3}$ .		[SHOW MORE] We get $P=Z$ , so $P$ is abelian.
6	We get the desired result.			Steps (3), (4), (5)	Step-combination.

Second part of proof: classifying the abelian groups

This classification follows from fact (7): the abelian groups of order $p^{3}$ correspond to partitions of 3, as indicated in the original statement of the classification.

Third part of proof: classifying the non-abelian groups

Given: A non-abelian group $P$ of order $p^{3}$ . Let $Z$ be the center of $P$ .

Previous steps: $Z$ is cyclic of order $p$ , and $P/Z$ is elementary abelian of order $p^{2}$ .

We first make some additional observations.

Step no.	Assertion/construction	Given data used	Previous steps used	Explanation
1	The derived subgroup (commutator subgroup) $P'$ equals $Z$ .	$P$ is non-abelian of order $p^{3}$ .	$P/Z$ is abelian, $Z$ has order $p$ .	[SHOW MORE] Since $P/Z$ is abelian, $P'$ is contained in $Z$ . Since $Z$ has prime order, the only possible subgroups are the trivial subgroup and $Z$ itself. The derived subgroup cannot be trivial since $P$ is non-abelian, hence the derived subgroup must be $Z$ .
2	We can find elements $a,b\in P$ such that the images of $a,b$ in $P/Z$ are non-identity elements of $P/Z$ that generate it.		$P/Z$ is elementary abelian of order $p^{2}$	[SHOW MORE] $P/Z$ is elementary abelian of order $p^{2}$ , hence is generated by a set of size two comprising non-identity elements. Choose $a,b$ to be arbitrary inverse images of these elements.
3	$Z,a,b$ together generate $P$ .
4	$a$ and $b$ do not commute.		Steps (2), (3)	[SHOW MORE] If $a$ and $b$ commute, then $C_{P}(a)$ contains $Z,a,b$ , hence equals all of $P$ . Thus, $a\in Z$ , so its image in $P/Z$ is the identity element, a contradiction to what we assumed.
5	Let $z=[a,b]$ . Then, $z$ is a non-identity element of $Z$ .		Steps (1), (4)	[SHOW MORE] We must have $z\in P'$ , which equals $Z$ by Step (1). By Step (4), $[a,b]$ is not the identity element. So $z$ is a non-identity element of $Z$ .

@@ Line 77: / Line 77: @@
 ! Step no. !! Assertion/construction !! Facts used !! Given data used !! Previous steps used !! Explanation
 |-
-| 1 || The derived subgroup (commutator subgroup) <math>P'</math> equals <math>Z</math>. || || <math>P</math> is non-abelian of order <math>p^3</math>. || <math>P/Z</math> is abelian, <math>Z</math> has order <math>p</math>. || <toggledisplay>Since <math>P/Z</math> is abelian, <math>P'</math> is contained in <math>Z</math>. Since <math>Z</math> has prime order, the only possible subgroups are the trivial subgroup and <math>Z</math> itself. The derived subgroup cannot be trivial since <math>P</math> is non-abelian, hence the derived subgroup must be <math>Z</math>.
+| 1 || The derived subgroup (commutator subgroup) <math>P'</math> equals <math>Z</math>. || || <math>P</math> is non-abelian of order <math>p^3</math>. || <math>P/Z</math> is abelian, <math>Z</math> has order <math>p</math>. || <toggledisplay>Since <math>P/Z</math> is abelian, <math>P'</math> is contained in <math>Z</math>. Since <math>Z</math> has prime order, the only possible subgroups are the trivial subgroup and <math>Z</math> itself. The derived subgroup cannot be trivial since <math>P</math> is non-abelian, hence the derived subgroup must be <math>Z</math>.</toggledisplay>
 |-
 | 2 || We can find elements <matH>a,b \in P</math> such that the images of <math>a,b</math> in <math>P/Z</math> are non-identity elements of <math>P/Z</math> that generate it. || || || <math>P/Z</math> is elementary abelian of order <math>p^2</math> || <toggledisplay><math>P/Z</math> is elementary abelian of order <math>p^2</math>, hence is generated by a set of size two comprising non-identity elements. Choose <math>a,b</math> to be arbitrary inverse images of these elements.</toggledisplay>